Brandon Daveler scite author profile

Brandon Daveler

4Publications

35Citation Statements Received

26Citation Statements Given

How they've been cited

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Affiliations

VA Pittsburgh Healthcare System, University of Pittsburgh

Publications

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Participatory design and validation of mobility enhancement robotic wheelchair

et al. 2015

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Abstract-The design of the mobility enhancement robotic wheelchair (MEBot) was based on input from electric powered wheelchair (EPW) users regarding the conditions they encounter when driving in both indoor and outdoor environments that may affect their safety and result in them becoming immobilized, tipping over, or falling out of their wheelchair. Phase I involved conducting a participatory design study to understand the conditions and barriers EPW users found to be difficult to drive in/over. Phase II consisted of creating a computer-aided design (CAD) prototype EPW to provide indoor and outdoor mobility that addressed these conditions with advanced applications. Phase III involved demonstrating the advanced applications and gathering feedback from end users about the likelihood they would use the advanced applications. The CAD prototype incorporated advanced applications, including selfleveling, curb climbing, and traction control, that addressed the challenging conditions and barriers discussed with EPW users (n = 31) during the participatory design study. Feedback on the CAD design and applications in phase III from end users (n = 12) showed a majority would use self-leveling (83%), traction control (83%), and curb climbing (75%). The overall design of MEBot received positive feedback from EPW users. However, these opinions will need to be reevaluated through user trials as the design advances.

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A Heuristic Approach to Overcome Architectural Barriers Using a Robotic Wheelchair

Candiotti

Daveler

Kamaraj

et al. 2019

IEEE Trans. Neural Syst. Rehabil. Eng.

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Usability Evaluation of a Novel Robotic Power Wheelchair for Indoor and Outdoor Navigation

Candiotti

Kamaraj

Daveler

et al. 2019

Archives of Physical Medicine and Rehabilitation

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Kinematics and Stability Analysis of a Novel Power Wheelchair When Traversing Architectural Barriers

Candiotti

Sundaram

Daveler

et al. 2017

Topics in Spinal Cord Injury Rehabilitation

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Electric-powered wheelchairs (EPWs) are essential devices for people with disabilities for mobility and quality of life. However, the design of common EPWs makes it challenging for users to overcome architectural barriers, such as curbs and steep ramps. Current EPWs lack stability, which may lead to tipping the EPW causing injury to the user. An alternative Mobility Enhancement Robotic Wheelchair (MEBot), designed at the Human Engineering Research Laboratories (HERL), was designed to improve the mobility of, and accessibility for, EPW users in a wide variety of indoor and outdoor environments. Seat height and seat inclination can be adjusted using pneumatic actuators connected to MEBot's 6 wheels. This article discusses the design and development of MEBot, including its kinematics, stability margin, and calculation of the center of mass location when performing its mobility applications of curb climbing/descending and attitude control. Motion capture cameras recorded the seat angle and joint motion of the 6 wheel arms during the curb climbing/descending process. The center of mass location was recorded over a force plate for different footprint configurations. Results showed that the area of the footprint changed with the location of the wheels during the curb climbing/descending and attitude control applications. The location of the center of mass moved ±30 mm when the user leaned sideways, and the seat roll and pitch angle were 0° and ±4.0°, respectively, during curb climbing and descending. Despite the user movement and seat angle change, MEBot maintained its stability as the center of mass remained over the wheelchair footprint when performing its mobility applications.

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Brandon Daveler

Participatory design and validation of mobility enhancement robotic wheelchair

A Heuristic Approach to Overcome Architectural Barriers Using a Robotic Wheelchair

Usability Evaluation of a Novel Robotic Power Wheelchair for Indoor and Outdoor Navigation

Kinematics and Stability Analysis of a Novel Power Wheelchair When Traversing Architectural Barriers

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